EP0536479A1

EP0536479A1 - Self-glazing lithium disilicate-containing glass-ceramics

Info

Publication number: EP0536479A1
Application number: EP92111206A
Authority: EP
Inventors: George Halsey Beall; Lina Maria Echeverria; Joseph Walter Morrissey; Joseph Eugene Pierson
Original assignee: Corning Inc
Current assignee: Corning Inc
Priority date: 1991-10-07
Filing date: 1992-07-02
Publication date: 1993-04-14
Anticipated expiration: 2012-07-02
Also published as: DE69204791D1; EP0536479B1; JPH07187710A; DE69204791T2; MX9205736A; BR9203278A; US5219799A

Abstract

This invention relates to glass-ceramic articles containing lithium disilicate crystals as the predominant crystal phase and consisting essentially, in weight percent, of 8-19% Li₂O, 0-5% Na₂O, 0-7% K₂O, 0-8% Na₂O+K₂O, 0-10% CaO, 0-6% SrO, 0-6% BaO, 2-12% Na₂O+K₂O+CaO+SrO+BaO, 0-7% ZnO, 0-11% Al₂O₃, 1.5-11% ZnO+Al₂O₃, with a molar ratio (Na₂O+K₂O):(ZnO+Al₂O₃) between 0.075-1.25, 65-80% SiO₂, and as a nucleating agent 1.5-7% P₂O₅ and/or 0.0001-0.1% Pd. Glass-ceramics having certain compositions within those ranges are self-glazing.

Description

Glasses having compositions approximating the stoichiometry of lithium disilicate (Li₂0.2Si0₂) require very high temperatures for melting and are notoriously unstable, i.e., they are very prone to devitrification, that latter characteristic to date having precluded the manufacture of glass-ceramic articles on a commercial scale therefrom due to the inadequacy of microstructural tailoring required for necessary property control. Thus, the fabrication of glass-ceramic articles containing lithium disilicate crystals as the predominant crystal phase (frequently utilizing P₂0₅ as a nucleating agent) has been reported in the art, such articles pruportedly exhibiting high mechanical strengths. Because of the inherent instability of the glass phase, however, the reproducibility in properties demanded in commercial production has been lacking. Nevertheless, on account of the high mechanical strengths demonstrated by glass-ceramic articles containing lithium disilicate crystals when those crystals are relatively uniformly fine-grained and homogeneously dispersed throughout the article, research has continued to devise precursor glass compositions and heat treatment schedules therefor which would yield sound glass-ceramic articles wherein the advantageous physical properties of lithium disilicate-containing glass-ceramics would be reproducible.
In summary, there is no discussion in the above prior art of stabilizing the properties of glass-ceramic bodies containing Li₂0.2Si0₂ as the predominant crystal phase through the addition to the precursor glass composition of a glass based upon the mineral chkalovite or a glass based upon potassium feldspar or a glass based upon anorthite. Furthermore, there is no description of the formation of glass-ceramic articles containing Li₂0.2Si0₂ as the predominant crystal phase which develop a self-glazed surface of high gloss.
Accordingly, the primary objective of the present invention was to devise glass compositions which would inherently be stable, thereby permitting a high degree of microstructural control during the development of crystals therein and imparting great flexibility in forming techniques, for example, drawing, floating, pressing, rolling, spinning, etc.
Another objective of the instant invention was to design glass compositions, which, upon being crystallized in situ via a heat treatment being applied thereto, would form glass-ceramic articles wherein the properties thereof are reproducible.
Yet another objective of the subject invention was to produce sound glass-ceramic articles which, during the crystallization heat treatment, develop a self-glazed surface of high gloss.

Summary of the Invention

Inasmuch as it was recognized that the fundamental factor preventing the preparation of sound glass-ceramic bodies containing lithium disilicate as the predominant crystal phase was the instability of the glass phase, studies were undertaken to find glass-forming ingredients which, when incorporated into the base glass composition approximating the stoichiometry of Li₂O·2SiO₂, would yield stable residual glasses in the glass-ceramic articles produced through heat treatment thereof. Those studies led to operable base precursor compositions consisting essentially, expressed in terms of weight percent on the oxide basis, of 8-19% Li₂O, 0-5% Na₂O, 0-7% K₂O, 0-8% Na₂O+K₂O, 0-10% CaO, 0-6% SrO, 0-6% BaO, 2-12% Na₂O+K₂O+CaO+SrO+BaO, 0-7% ZnO, 0-11% Al₂O₃, 1.5-11% ZnO+Al₂O₃, with a molar ratio (Na₂O+K₂O+CaO+SrO+BaO):-(ZnO+Al₂O₃) between 0.075-1.25, 65-80% SiO₂, and as a nucleating agent 1.5-7% P₂O₅ and/or 0.0001-0.1% Pd. The preferred compositions contain at least 2% ZnO and/or 2% K₂O or 1% CaO and/or 3% Al₂O₃.
In our laboratory investigations to locate desirable glass-forming ingredients for incorporation into the base Li₂O·2SiO₂ composition which would improve parent glass stability and yield highly durable glasses in the resulting glass-ceramic products, certain stoichiometric compositions conveniently referred to in terms of natural mineral analogs were added as described below. Those additions were found to be not only capable of providing glass-ceramic articles exhibiting high mechanical strength and toughness values, those values being reproducible, but also to improve the melting behavior thereof.

Chkalovite Glasses

Stable glass-ceramic articles were prepared through additions of about 10-20% by weight of glasses having compositions based on the mineral chkalovite (Na₂O·Zno·2SiO₂). The base composition was extended to include R₂O·ZnO·xSiO₂, where R was Na and/or K, and x ranged up to 10. Sound glass-ceramic bodies were produced from all compositions. Whereas the major proportion of the chkalovite component remains in the residual glass of the final glass-ceramic, any excess silica resulting from the additions is precipitated as crystals in the form of cristobalite or α-quartz.

Potassium Feldspar Glasses

About 10-20% by weight of glasses having compositions based on potassium feldspar (K₂O·Al₂O₃·6SiO₂) were incorporated into the base Li₂O·2SiO₂ glass composition. Again, sound glass-ceramic bodies were produced from all compositions.

Anorthite Glasses

In like manner to the chkalovite and potassium feldspar glasses, about 10-50% by weight of glasses having compositions based on the anorthite stoichiometry (CaO·Al₂O₃·SiO₂) were included in the base Li₂O·2SiO₂ glasses. Yet again, sound glass-ceramic articles were prepared from all compositions.
Glass-ceramics have been marketed as articles of tableware for a number of years by Corning Incorporated, Corning, New York under such trademarks as CENTURA, PYROCERAM, and SUPREMA. The predominant crystal phase in the CENTURA ware is a combination of nepheline and celsian and/or hexacelsian. Hexacelsian comprises the predominant crystal phase in the PYROCERAM tableware, and potassium fluorrichterite constitutes the predominant crystal phase in the SUPREMA tableware with a minor amount of cristobalite. Each of those products requires a glaze having a lower coefficient of thermal expansion than the glass-ceramic body to which it is to be applied in order to provide a decorative high surface gloss and to enhance the mechanical strength of the glass-ceramic body.
Because of the inherent high mechanical strength and toughness exhibited by the present inventive glass-ceramics articles of tableware can be fashioned therefrom having thinner wall thicknesses than those above-described commercial products. Such thin cross sections lead to products demonstrating translucencies approaching those of quality china, e.g., bone china.
We have further found that, by modifying the base compositions of the precursor glasses, glass-ceramic articles can be prepared which are self-glazing; i.e., as the precursor glass body is heat treated to cause the development of nuclei therein and the subsequent growth of crystals on those nuclei, a glassy layer is formed which diffuses to the surface. This self-glazing effect is controlled by the heat treatment schedule to which the glass body is subjected. It is especially dependent upon the length of the nucleation period. Hence, if surface nucleation is not completely depressed, crystals will be developed which protrude through the glassy layer, thereby giving rise to a dull surface. Accordingly, a long period of nucleation is demanded to assure the dominance of body nucleation and a minimum of surface nucleation. The utilization of higher levels of nucleating agent, however, can reduce the time necessary for nucleation. The rate of heating the nucleated glass to the crystallization temperature and the length of time to which the nucleated glass is exposed to the crystallization temperature can also affect the self-glazing phenomenon.
These self-glazing glass-ceramics can be deemed to comprise a mixture of lithium disilicate, a nucleating agent, and an accessory phase. The accessory phase is founded in the incorporation of glass compositions based upon the formulae R₂O·ZnO·2-10SiO₂, where R₂O is Na₂O and/or K₂O, K₂O·Al₂O₃·6SiO₂SiO₂ and/or RO·Al₂O₃·2-6SiO₂, where RO is selected from the group of CaO, SrO, and BaO. In like manner to the basic precursor glasses reported above, excess SiO₂ (customarily up to about 10% by weight) can be included. To assure obtaining the desired self-glazing phenomenon, the accessory glass component will be incorporated in an amount of at least 20% by weight, preferably at least 30% by weight. The glass-ceramic articles prepared with 30% by weight of the accessory component contain about 60% by weight lithium disilicate. Additions of the accessory glass component up to 50% by weight have been made, but the level of lithium disilicate crystals then drops to about 40% by weight, with consequent reduction in mechanical strength. Therefore, a 40% addition of an accessory glass component has been deemed a practical maximum.
The introduction of CaO in the accessory component in conjunction with Al₂O₃ results in the following two advantages: (1) it permits the use of spodumene, petalite, and/or amblygonite as batch materials for Li₂O, rather than the more expensive Li₂CO₃ (CaO can be present as an impurity in those minerals); and (2) it increases the overall extent of crystallinity in the final product, thereby allowing a reduction in the level of Li₂O·2SiO₂ crystals without seriously deteriorating the mechanical properties demonstrated by the glass-ceramic. Both factors lead to a net reduction in glass batch cost and frequently a faster melting rate of the batch.
Evidence of very high levels of crystallization (>75% by weight) with concomitant low levels of residual glass, is provided in x-ray diffractometry analyses which have indicated that the crystal assemblage of the CaO/Al₂O₃-containing glass-ceramics consists of lithium disilicate plus minor amounts of spodumene, cristobalite, and wollastonite. Based upon that evidence, it is believed apparent that most of the CaO-Al₂O₃-SiO₂ accessory component goes into the crystal assemblage, instead of remaining within the residual glass.
Laboratory investigations have indicated that glass compositions particularly desirable for forming self-glazing glass-ceramic bodies will consist essentially, expressed in terms of weight percent on the oxide basis, of 2-10% total of 0-7% K₂O and/or 0-8% CaO and/or 0-6% SrO and/or 0-6% BaO, 0-7% ZnO, 0-10% Al₂O₃, 1.5-10% Al₂O₃+ZnO, with a molar ratio (K₂O+CaO+SrO+BaO):(Al₂O₃+ZnO) between 0.1-0.8, 9-18% Li₂O, and 65-77% SiO₂, with P₂O₅ being the preferred nucleating agent at levels of about 2-6%. The optional inclusion of ZrO₂ in amounts up to 3% can be useful in achieving higher levels of crystallization in the final product. Such crystallization reduces the translucency of the product, however.
In general, the operable nucleation temperatures will vary between about 475°-700°C and crystallization will take place over the 750°-1000°C temperature interval. As can be appreciated, the periods of time required for essentially complete nucleation and crystallization are related to the thickness dimension of the product. Hence, thin-walled articles will require shorter periods of time for each heat treating step than articles of thicker cross section.
To assure the most preferred self-glazing, the precursor glass articles containing the accessory components will be exposed to temperatures between about 475°-625°C for an extended period of time to achieve a high degree of nucleation. For articles having a configuration suitable for tableware, that period of exposure will be in excess of one hour, preferably in the vicinity of three hours. Laboratory experience has demonstrated that a slow increase in temperature over the nucleation interval, rather than a dwell period at a specific temperature within that interval, frequently results in more complete nucleation. Thereafter, the temperature of the nucleated glass article is raised relatively quickly to within the crystallization range and the article is retained therewithin for about 1-4 hours to secure essentially complete crystallization.
Two factors other than gloss and translucency must be addressed in the manufacturing process for producing tableware; viz., the relative fluidity of the precursor glass during the heat treating step and the level of internal stress exerted on the ware during crystallization thereof. Relative fluidity provides a measure of thermal deformation exhibited by the glass article during the heat treatment process. The occurrence of high internal stresses during crystallization is of particular significance in glasses with low relative fluidity, inasmuch as they may crack or mechanically deform the ware. The sharpness and height of the exothermic peak observed via differential thermal analysis (DTA) can provide a measure of the stresses exerted over the ware during crystallization. Thus, where the exothermic peak is relatively short and broad, the nucleation/crystallization density change in the glass is less rapid and, hence, there is less stress buildup.
Where the articles will be crystallized in contact with formers, the precursor glass must be so designed that it will sag somewhat during the heat treatment thereof such that it can be made to conform to the configuration of the former. Thus, the relative fluidity of the glass over the nucleation and crystallization temperature intervals must be adequate to permit such forming.
In summary, careful control of the viscosity level of the glass during the crystallization process yields the most advantageous product. Thus, the most preferred products result when the viscosity level of the glass is held between about 1x10¹⁰-5x10¹¹ poises and the heat up rate is regulated to assure that those values are maintained.
Glass-ceramic articles containing Li₂O·2SiO₂ as the predominant crystal phase are white in color. However, the addition in amounts of about 0.01-7% by weight total of such colorants as Ce0₂, CdS and cadmium sulfoselenide and the transition metal oxides, e.g., Co₃0₄, Ni0, Fe₂0₃, Mn0₂, Cu0, Cr₂0₃, and V₂0₅, to the precursor glass compositions in order to impart color is well known in the glass-ceramic art. The high strength and toughness values displayed by the inventive materials permit their use as tableware in thinner cross section than conventional ceramic materials employed for that application. The glossy surface and body translucence impart a very attractive appearance to the inventive materials. Moreover, the intensity of surface glass can be controlled through control of the top heat treatment (crystallization) temperature. Translucency is a key aesthetic property inasmuch as it adds depth and, hence, a third dimension to tableware materials.
The prior art is represented by the following Patents: British Patent No. 924,996, British patent No. 943,599, U.S. Patent No. 3,006,775, U.S. Patent No. 3,231,456, U.S. Patent No. 3,236,610, U.S. Patent No. 3,238,085, U.S. Patent No. 3,460,987, U.S. Patent No. 3,804,608, U.S. Patent No. 3,977,857, U.S. Patent No. 4,414,282, and U.S. Patent No. 4,672,152.

Description of Preferred Embodiments

Table I records a group of precursor glass compositions expressed in terms of parts by weight on the oxide basis demonstrating the parameters of the inventive compositions. Because the sum of the recited components totals or closely approximates 100, for all practical purposes the individual values reported in Table I may be deemed to represent weight percent. Examples 1-8 reflect operable base compositions and Examples 1-4 and 6-8 illustrate compositions capable of forming self-glazing glass-ceramic articles exhibiting high gloss. Examples 9 and 10 present glass compositions close to, but outside of, the ranges found to be necessary to yield the glass-ceramics of the instant invention. The actual batch ingredients may comprise any materials, either an oxide or other compound, which, when melted together with the other constituents, is converted into the desired oxide in the proper proportions. For example, Li₂CO₃ may constitute the source of Li₂O and AlPO₄ may comprise the source of both P₂O₅ and Al₂O₃.
The batch ingredients were compounded, thoroughly mixed together to assist in securing a homogeneous melt, and charged into platinum crucibles. The crucibles were moved into a furnace operating at about 1450°C and the batches melted for about 16 hours. The melts were thereafter poured into steel molds to yield glass slabs having dimensions of about 5"x5"x0.5" (^∼12.7x12.7x1.3 cm), and those slabs were transferred immediately to an annealer operating at about 450°C.
It will be recognized that, whereas the above description is drawn to laboratory activity only, the glasses operable in the subject invention can be melted in large commercial melting units and formed into desired shapes via conventional glass melting and forming practice. It is only necessary that the compositions be fired at sufficiently high temperatures and for a sufficient length of time to produce a homogeneous melt, and thereafter the melt is cooled and simultaneously shaped into a glass body which customarily will then be annealed.

After the glass slabs were removed from the annealer, samples for testing purposes were cut from each, e.g., test bars for measuring modulus of rupture, and those test samples plus the remainder of the slabs subjected to the heat treatments reported in Table II, whereby the glasses were crystallized in situ to glass-ceramics. Table II also records the visual appearance of each glass-ceramic and values of various properties exhibited by the precursor glass and/or the resultant glass-ceramic, such as annealing point (A.P.) and strain point (S.P.), listed in terms of °C, density (Dens.), recorded in terms of g/cm³, linear coefficient of thermal expansion (Exp), reported in terms of x10⁻⁷°C, modulus of rupture (MOR), cited in terms of Ksi, and toughness (Tough), expressed in terms of MPa√m, as determined in accordance with measurement techniques conventional in the art. Examples 9 and 10 cracked severely when subjected to the crystallization heat treatment.

TABLE II

Example	Glass Properties			Heat Treatment	Visual Descr.	Glass-Ceramic Properties
	A.P.	S.P.	Exp.			MOR	Exp.	Tough.
1	431	401	112	300°/hr to 480°C Hold for 1 hr	High gloss, white	28.5	127	2.83
1	431	401	112	300°/hr to 800°C Hold for 4 hrs	High gloss, white	28.5	127	2.83
2	440	410	109	300°/hr to 480°C Hold for 1 hr	High gloss, white	33.9	101	3.0
2	440	410	109	300°/hr to 850°C Hold for 2 hrs	High gloss, white	33.9	101	3.0
3	452	423	100	300°/hr to 650°C Hold for 4 hrs	High gloss, white	31.4	78	3.3
3	452	423	100	300°/hr to 950°C Hold for 4 hrs	High gloss, white	31.4	78	3.3
4	495	462	--	200°/hr to 500°C 10°hr to 560°C	High gloss, white	22.1	50	--
4	495	462	--	300°/hr to 850°C Hold for 2 hrs	High gloss, white	22.1	50	--
5	414	443	109.2	300°/hr to 650°C Hold for 4 hrs	White	29.0	98.5	2.79
5	414	443	109.2	300°C/hr to 850°C Hold for 4 hrs	White	29.0	98.5	2.79
6	442	476	81.5	300°/hr to 500°C 10°/hr to 560°C	High gloss, white	20.0	49.2	1.98
6	442	476	81.5	300°/hr to 850°C Hold for 2 hrs	High gloss, white	20.0	49.2	1.98
7	503	541	66.8	300°/hr to 650°C Hold for 2 hrs	High gloss, white	17.8	76	--
7	503	541	66.8	300°/hr to 875°C Hold for 4 hrs	High gloss, white	17.8	76	--
8	568	501	80.2	300°/hr to 650°C Hold for 2 hrs	High gloss, white	22.0	47.2	1.62
8	568	501	80.2	300°/hr to 850°C Hold for 4 hrs	High gloss, white	22.0	47.2	1.62

Claims

A glass-ceramic article containing Li₂O·2SiO₂ as the predominant crystal phase consisting essentially, expressed in terms of weight percent on the oxide basis, of 8-19% Li₂O, 0-5% Na₂O, 0-7% K₂O, 0-8% Na₂O+K₂O, 0-10% CaO, 0-6% SrO, 0-6% BaO, 2-12% Na₂O+K₂O+CaO+SrO+BaO, 0-7% ZnO, 0-11% Al₂O₃, 1.5-11% ZnO+Al₂O₃, with a molar ratio (Na₂O+K₂O+CaO+SrO+BaO):(Al₂O₃+ZnO) between 0.075-1.25, 65-80% SiO₂, and as a nucleating agent 1.5-7% P₂O₅ and/or 0.0001-0.1% Pd.
A glass-ceramic article according to claim 1 containing at least 2% ZnO and/or 2% K₂O.
A glass-ceramic article according to claim 1 containing at least 1% CaO and/or 3% Al₂O₃.
A glass-ceramic article according to claim 1 also containing 0.01-7% total of at least one member of the group consisting of CdS, cadmium sulfoselenide, CeO₂, Co₃O₄, Cr₂O₃, CuO, Fe₂O₃, MnO₂, NiO, and V₂O₅.
A self-glazed glass-ceramic article containing Li₂O·2SiO₂ as the predominant crystal phase consisting essentially, expressed in terms of weight percent on the oxide basis, of 9-18% Li₂O, 2-10% total of at least one member of the group consisting of 0-7% K₂O, 0-8% CaO, 0-6% SrO, and 0-6% BaO, 0-7% ZnO, 0-10% Al₂O₃, 1.5-10% Al₂O₃+ZnO, with a molar ratio (K₂O+CaO+SrO+BaO):(Al₂O₃+ZnO) between 0.1-0.8, 65-77% SiO₂, and as a nucleating agent 2-6% P₂O₅.
A self-glazed glass-ceramic article according to claim 5 also containing up to 3% ZrO₂.
A self-glazed glass-ceramic article according to claim 5 also containing 0.01-7% total of at least one member of the group consisting of CdS, cadmium sulfoselenide, CeO₂, Co₃O₄, Fe₂O₃, CuO, Cr₂O₃, MnO₂, NiO, and V₂O₅.